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Asteroid Explorer, Hayabusa2, Reporter Briefing

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Asteroid Explorer, Hayabusa2, Reporter Briefing Asteroid explorer, Hayabusa2, reporter briefing November 30, 2020 JAXA Hayabusa2 Project Topics Regarding Hayabusa2 Results from TCM-3 Details of capsule separation and re-entry Preparation status for capsule collection 2020/11/30 Hayabusa2 reporter briefing 2 Contents 0. Hayabusa2 and mission flow outline 1. Current status and overall schedule of the project 2. Results from TCM-3 3. Details of capsule separation and re-entry 4. Preparation status for capsule collection 5. Outreach 6. Future plans 2020/11/30 Hayabusa2 reporter briefing 3 Overview of Hayabusa2 Objective We will explore and sample the C-type asteroid Ryugu, which is a more primitive type than the S-type asteroid Itokawa that Hayabusa explored, and elucidate interactions between minerals, water, and organic matter in the primitive solar system. By doing so, we will learn about the origin and evolution of Earth, the oceans, and life, and maintain and develop the technologies for deep-space return exploration (as demonstrated with Hayabusa), a field in which Japan leads the world. Expected results and effects By exploring a C-type asteroid, which is rich in water and organic materials, we will clarify interactions between the building blocks of Earth and the evolution of its oceans and life, thereby developing solar system science. Japan will further its worldwide lead in this field by taking on the new challenge of obtaining samples from a crater produced by an impacting device. We will establish stable technologies for return exploration of solar-system bodies. Features: (Illustration: Akihiro Ikeshita) World’s first sample return mission to a C-type asteroid. Hayabusa 2 primary specifications World’s first attempt at a rendezvous with an asteroid and performance of observation before and after projectile impact from an impactor. Mass Approx. 609 kg Comparison with results from Hayabusa will allow deeper understanding of the distribution, origins, and Launch 3 Dec 2014 evolution of materials in the solar system. Mission Asteroid return Arrival 27 June 2018 International positioning Deoarture 13 Mov 2019 Japan is a leader in the field of primitive body exploration, and visiting a type-C asteroid marks a new Earth return 6 Dec 2020 (plan) accomplishment. Stay at asteroid Approx. 18 months This mission builds on the originality and successes of the Hayabusa mission. In addition to developing planetary Target body Near-Earth asteroid Ryugu science and solar system exploration technologies in Japan, this mission develops new frontiers in exploration of primitive heavenly bodies. Primary instruments NASA too is conducting an asteroid sample return mission, OSIRIS-REx (launch: 2016; asteroid arrival: 2018; Sampling mechanism, re-entry capsule, optical cameras, laser Earth return: 2023). We will exchange samples and otherwise promote scientific exchange, and expect further range-finder, scientific observation equipment (near-infrared, scientific findings through comparison and investigation of the results from both missions. thermal infrared), impactor, miniature rovers. 2020/11/30 Hayabusa2 reporter briefing 4 Mission flow Launch Earth swing-by Ryugu arrival MI NE RVA-II1 separation MASCOT Sep 21, 2018 Dec 3, 2014 Dec 3, 2015 June 27, 2018 separation Oct 3, 2018 Target marker Ryugu separation departure Oct 25, 2018 Nov 13, 2019 Target Target marker Earth return complete marker separation Impactor (SCI) Dec. 6, 2020 MI NE RVA-II2 separation Second May 30, 5 April, 2019 separation Sept. 17, touchdown 2019 First touchdown (image credit: illustrations including spacecraft July 11, 2019 by Akihiro Ikeshita, others by JAXA) Oct. 3, 2019 2019 Feb 22, 2019 2020/11/30 Hayabusa2 reporter briefing 5 1. Current project status & schedule overview – On November 25, we obtained permission from Australia to transition to the re-entry orbit. Current – TCM-3 was conducted on November 26, and the control maneuver to place the spacecraft into the status: atmospheric entry orbit towards Woomera, Australia was completed. – After precisely estimating the resultant orbit, it was determined that it was unnecessary to correct the TCM-3 orbit itself, and it was decided to move onto the next TCM-4. – In Woomera, the preparations underway for re-entry capsule recovery. 2015 2016 2017 2018 2019 2020 Schedule overview 12 3 10 12 4 6 7 ../- "' 12 $$,1/126 ,(1( * 4(,&!6 -2/,$61- 01$/-(# 01$/-(#./-5(+(16-.$/ 1(-,0 /1'/$12/, Event -.$/ 1(-, * 2,"' /1'04(,&!6 //(3 * 162&2 $. /12/$%/-+62&2 .02*$/$$,1/6 $" $" 2,$ -3 $" 89 1$01-.$/ 1(-,0 -21'$/,'$+(0.'$/$01 1(-, 6 -.$/ 1(-,0 .1(" *, 3(& 1(-, -* / "-,)2,"1(-, "1 6 6 2* -3 $" $.1 -,$,&(,$-.$/ 1(-,07 / 2, / 6 -3 ./ , 2, $" $! 6 8(+ &$"/$#(1:9 2020/11/30 Hayabusa2 reporter briefing 6 2. Results from TCM-3 • On November 25, we obtained permission from the Commonwealth Return Safety Officer (CRSO) to transition Hayabusa2 onto the re-entry trajectory to the Woomera Prohibited Area (WPA) in Australia. #Judgement found no problem with navigation, guidance, planning, spacecraft or ground system) • On November 26, TCM-3, the third precision orbit control using the chemical engines (RCS) was performed, and the orbit correction was achieved as planned#TCM: Trajectory Correction Maneuver$. • The main control for TCM-3 was performed around 16:00 JST and the controlled correction (trim) around 17:00. The orbit control amount was about 1.2 m/s. % Atmospheric entry target "10km TCM-3 Deflection angle 0.0085! Passing Flight speed (vs Earth) 4.36 km/s " Orbit change amount (thruster injection altitude acceleration amount) 1.2m/s 290km # % $ 2020/11/30 Hayabusa2 reporter briefing 7 2. Results from TCM-3 For each TCM, there are 2 Orbit guidance by TCM cycles of practice/production Team movement at TCM-4 Ground Edge of surface atmosphere 11/30 1-12 JST altitude 0km) (altitude 200km Orbit determination: measure and calculate the flight position of the spacecraft. JAXAFujitsuJPL Before ↓ TCM1 11/30 13-14 JST In precision Orbit evaluation: evaluate calculation results of the flight position guidance, a virtual and chose one from 3 solutions (JAXA, Fujitsu, JPL, NEC) ↓ target is set around 11/30 14-19 JST After After the Earth and orbit Planned route Trajectory plan: create trajectory correction plan JAXANEC TCM3 TCM4 control is ↓ 11/30 17-22 JST performed to aim After Attitude plan: attitude plan for injection, create thruster injection for a specific point capsule plan (JAXA) on that target. separation After TCM1 ↓ Before Before TCM2 TCM3 11/30 night 22-23 JST Confirm plan: Final confirmation meeting (TCM Go/No Go) Guidance target The Australian permit was obtained after TCM3 area at TCM3 100km ↓ (inside Woomera) 12/1 all day image credit: JAXA Actual operation 2020/11/30 Hayabusa2 reporter briefing 8 2. Results from TCM-3 TCM3TCM4 concept ü TCM3 adjusts the course to one that enters the atmosphere over Woomera. ü TCM4 modifies this trajectory to land closer and more accurately to the area where the recovery team awaits. 2020/11/30 Hayabusa2 reporter briefing 9 3. Details of capsule separation & re-entry Schedule Event Time (JST) Earth distance (altitude) TCM-4orbit control correction 12/1 Around 16:00 1.74 million km Capsule separation 12/5 14:30 220,000 km TCM-5orbit control correction to 12/5 15:3018:00 200,000 – 160,000 km depart from the Earth’s sphere (spacecraft) Spacecraft enters shadowed area 12/6 1:57 12,000km (spacecraft) Capsule imaging 12/6 2:2830 700km300km (spacecraft) Capsule atmospheric entry 12/6 2:2829 120km (capsule) Spacecraft exits shadow 12/6 2:31 350km (spacecraft) Parachute deployment 12/6 2:3133 117km (capsule) Capsule landing 12/6 2:4757 0km (capsule) 2020/11/30 Hayabusa2 reporter briefing 10 3. Details of capsule separation & re-entry Re-entry explanatory diagram 2020/11/30 11 3. Details of capsule separation & re-entry ! #!' " #!" # ) ""! %%% $#!"! #"!""" !!(!#!!"# "%' " (&#! #"!# %!#"# %!#" %! 2020/11/30 Hayabusa2 reporter briefing 12 4. Preparation status for capsule collection • The main team arrived at Woomera on 11/24 and began settling up antennas, etc. • The temperature at the time of installation was over 40 . Work was under the scorching sun while trying to prevent heat stroke. ℃ Assembly of DFS antenna Completed assembly of DFS antenna 2020/11/30 Hayabusa2 reporter briefing 13 4. Preparation status for capsule collection • The main team arrived at Woomera on 11/24 and began settling up antennas, etc. • The temperature at the time of installation was over 40 . Work was under the scorching sun while trying to prevent heat stroke. ℃ MRS antenna assembly complete MRS antenna assembly complete 2020/11/30 Hayabusa2 reporter briefing 14 4. Preparation status for capsule collection • The QLF clean booth has been set up and is being tested. 2020/11/30 Hayabusa2 reporter briefing 15 5. Outreach Ryugu & Hayabusa2 return observation campaign • Number of registered campaigns135 • Many reports (28 as of November 26) have already been made of observations of Ryugu. • For observations of Hayabusa2 just before re-entry, data for the observation will be provided to registrants. • A special observation team (nicknamed “Hayabusan2”) was formed among the registered observers and if the observation is successful, the position and luminosity will be measured. Also, attempts will be made to try and observe the separated capsule. (24 teams as of November 26) The Subaru Telescope succeeded in imaging Hayabusa2 on November 20 (Hawaii time) • Organisers: Hayabusa2 Project, Japan Public
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